Ch 3: Bioenergetics

Question 1

Cell membrane

Answer 1

Semipermeable barrier also called sarcolemma in skeletal muscle cells separates cell from extracellular environment

Question 2

Nucleus

Answer 2

Contains genes composed of DNA. DNA regulates protein synthesis, which determines cell structure and function.

Question 3

Cytoplasm

Answer 3

Fluid portion of cell called sarcoplasm in muscle cells; contains organelles (mitochondria) and enzymes (enzymes for breaking down glucose)

Question 4

Metabolism

Answer 4

The sum of all chemical reactions that occur in the body

Anabolic and Catabolic reactions

Question 5

Anabolic Reactions

Answer 5

synthesis of molecules

Question 6

Catabolic reactions

Answer 6

breakdown of molecules

Question 7

Bioenergetics

Answer 7

Metabolic pathways that convert energy from foodstuffs (nutrients: fats, proteins, carbohydrates) into a usable form of energy for cell work

Question 8

All chemical reactions involve a change in

Answer 8

energy

Question 9

Endergonic Reactions

Answer 9

Energy required (consumed)
-positive change in energy

Endergonic reactions use the energy released by exergonic reactions

Question 10

Exergonic Reactions

Answer 10

Energy released (produced)
- negative change in energy

Exergonic reactions power Endergonic reactions

Question 11

Why are oxidation-reduction always coupled reactions?

Answer 11

because a molecule cannot become oxidized unless it donates electrons to another molecule

Question 12

Oxidation-reduction reactions often involve

Answer 12

the transfer of hydrogen atoms rather than free electrons

• hydrogen atom contains one electron
• a molecule that loses a hydrogen also loses an electron, therefore it is oxidized

Question 13

Oxidation reaction

Answer 13

Removing electrons (and hydrogen) from a molecule

Reducing agents: donate electrons and become oxidized
(NADH is reducing agent)

Question 14

Reduction reaction

Answer 14

Adding electrons (and hydrogen) to a molecule

Oxidizing agents: accept electrons and become reduced
(NAD is oxidizing agent)

Question 15

What is the role of NAD and FAD in the ETC?

Answer 15

they play an important role in transfer of electrons
- carrier molecules during bioenergetic reactions

Question 16

Enzymes

Answer 16

are protein catalysts that regulate the speed of chemical reactions in the body

• increase the rate of a cellular chemical reaction (and rate of product formation) by lowering the energy of activation
• cannot change the total amount of energy released from a reaction

Question 17

Kinases

Answer 17

add a phosphate group

Question 18

dehydrogenases

Answer 18

remove hydrogen atoms

Question 19

Oxidases

Answer 19

Catalyze oxidation-reduction reactions involving oxygen

Question 20

Isomerases

Answer 20

rearrangement of the structure of molecules

Question 21

How does temperature affect enzymes?

Answer 21

• a small rise in body temperature increases enzyme activity
• exercise results in increased body temperature
• large increase in body temperature can denature enzymes and decrease activity

Question 22

How does pH affect enzymes?
How does exercise affect pH?

Answer 22

Changes in pH (increase or decrease) can decrease enzyme activity
- high intensity exercise decreases muscle pH (makes more acidic)

Question 23

During exercise, the primary nutrients used for energy are

Answer 23

fats and carbohydrates

Question 24

Carbohydrates

Answer 24

1 gram —> 4 kcals

composed of carbon, hydrogen and oxygen

exists in 3 forms
- monosaccharides
- disaccharides
- polysaccharides: complex carbohydrates

Question 25

Glycogen is a polysaccharide stored in

Answer 25

our muscle and liver cells

Question 26

Glycogenolysis

Answer 26

process by which glycogen is broken down into glucose

Question 27

Glucose role in the body

(in muscle cells; and in liver cells)

Answer 27

• in muscle cells, glucose serves as source of energy for muscle contraction
• in liver cells, glucose released in blood stream and transported to body tissues

Question 28

Why is glycogen synthesis an ongoing process?

Answer 28

Because glycogen stores are depleted within a few hours of prolonged exercise.

Question 29

Fats

Answer 29

1 gram —> 9 kcals

composed of carbon, hydrogen and oxygen. but the ratio of carbon to oxygen in fats is greater than in carbs

• ideal fuel for prolonged exercise

Phospholipids and steroids are not used for energy.

Question 30

Fatty acids

Answer 30

the primary type of fat used by muscles for energy

Question 31

Triglycerides

Answer 31

fatty acids are stored as triglycerides in fat and muscle cells

Question 32

Lipolysis

Answer 32

process of breaking down triglycerides into glycerol and fatty acids

Question 33

Proteins

Answer 33

1 gram—> 4 kcals

composed of subunits called amino acids

• numerous structural and regulatory functions in the body… however energy is not a primary function.

Question 34

Proteins:
Energy production in the liver

Answer 34

Alanine can be converted to glucose (gluconeogenesis) and stored as glycogen

• liver glycogen can be broken down into glucose and used by working muscles

Question 35

Gluconeogenesis

Answer 35

Forming new glucose from protein (alanine)

Question 36

Proteins:
Energy production in muscle

Answer 36

Many amino acids (alanine, isoleucine, leucine, and valine) can be converted into “metabolic intermediates” which can be used as fuel in muscle bioenergetic pathways

Question 37

ATP

Answer 37

energy currency of life

muscle cells don’t store large amounts of ATP

Question 38

3 Metabolic Pathways of ATP Production:

Answer 38

1. Phosphocreatine (PC) Breakdown
2. Glycolysis
3. Oxidative Phosphorylation

Question 39

Phosphocreatine Breakdown

Answer 39

ADP + PC —> ATP + C

PC donates phosphate and bond energy to ADP to form ATP aka substrate level phosphorylation

anaerobic (oxygen independent)

occurs in sarcoplasm

Question 40

Glycolysis

Answer 40

Glucose —> 2 ATP + 2 Pyruvate or 2 lactate
Transfers bond energy from glucose to rejoin phosphate to ADP to make ATP. Breaks down glucose to form 2 pyruvate or lactate

anaerobic (oxygen independent)

occurs in sarcoplasm of muscle cells

• can produce ATP rapidly
• every molecule of glucose requires 2 ATP

Produces 2 ATP

Question 41

Oxidative phosphorylation

Answer 41

ATP formation in electron transport chain

• the vast majority of ATP formed in cells comes from oxidative phosphorylation, which occurs in mitochondria

Aerobic (oxygen dependent)

occurs in mitochondria

Question 42

Substrate-level phosphorylation

Answer 42

PC Breakdown

Phosphate and energy are transferred to ADP to form ATP

• most rapid method of ATP Production
• provides energy for muscular contraction at onset of exercise and during short term, high intensity exercise
• very small PC stores in the muscle cell… so limited capacity for ATP production via this system

Question 43

Glycogen is only minimally stored in the sarcoplasm, so most glucose comes from

Answer 43

liver glycogenolysis

• regardless of the source of glucose for glycolysis, glucose has to be phosphorylated to form glucose 6-phosphate

Question 44

Glucose obtained from glycogen

Answer 44

Does not require ATP to form glucose-6-phosphate, but instead uses inorganic phosphate (Pi) located in the cell

When glucose is obtained from glycogen as opposed to glucose— 3 ATP is formed bc only 1 ATP is invested and 4 are produced still

Question 45

In glycolysis, NAD+

Answer 45

accepts a H+ atom

• the NAD+ must be restored, or glycolysis will stop

Question 46

Two ways to regenerate NAD+

Answer 46

1. If sufficient O2, the hydrogens from NADH can be shuttled into the mitochondria, where they can contribute to the aerobic production of ATP (aerobic)
2. If insufficient O2, pyruvate can accept H+ ions to form lactate (anaerobic)

Question 47

Pyruvate —> Lactate (Lactic Acid)

Answer 47

If pyruvate and NADH are being produced faster than aerobic metabolism cab use them, then lactate is formed

aka

if there is no oxygen, then pyruvate turns into lactate
but if oxygen is present, we continue to the Kreb’s cycle

lactate dehydrogenase: converts pyruvate to lactate

Question 48

Lactate Accumulation

Answer 48

Increases tissue acidity, stressing the buffering systems

associated with fatigue, during intense exercise

Question 49

Lactate Removal

Answer 49

Used as fuel for aerobic metabolism

Used as a substrate for gluconeogenesis in liver

Question 50

Gluconeogenesis

Answer 50

forming glucose from lactate and store in the liver

Question 51

Lactic acid in the body

Answer 51

At normal pH, lactic acid rapidly disassociates into lactate and a H+ ion so lactic acid rarely exists in the body

lactate— conjugate base

Question 52

Aerobic ATP Production

Answer 52

• when oxygen is present, pyruvate molecules from glycolysis can be used for aerobic production of ATP

occurs in mitochondria

Involves the interaction of 2 cooperating metabolic pathways:
- Krebs cycle (citric acid cycle/ TCA (tricarboxylic acid))
- Electron Transport Chain

Oxygen does not participate in the Krebs cycle, but it is the final hydrogen acceptor at the end of the ETC (H2 + O—> H2O)

Question 53

3 stage process of aerobic ATP Production

Answer 53

1. Formation of acetyl-coA
2. Oxidation of acetyl-coA in Krebs cycle (remove electron and H+)
3. Oxidative phosphorylation (ATP formation) in the electron transport chain

Products of catabolism must first be shuttled from the cytoplasm into the mitochondrial matrix in order to be converted into Acetyl-coA

Question 54

Krebs cycle

Answer 54

Removes hydrogen, electrons and associated energy from nutrients

• Pyruvate forms acetyl-coA and CO2
• Oxaloacetate mixes with acetyl-coA to form citrate (enzyme: citrate synthase)
• the goal is to keep forming oxaloacetate

3 NADH and 1 FADH is formed

2 molecules of CO2 are produced

1 glucose—> 2 pyruvate –> 2 acetyl-CoA –> 2 turns of the Krebs cycle

Question 55

Krebs cycle total after 2 turns

Answer 55

6 NADH + H+
2 FADH2
2 GTP (2ATP)
4 CO2

In summary, the Krebs cycle completes the oxidation of foodstuffs, produces CO2 and provides the electrons necessary for aerobic formation of ATP

Question 56

Triglycerides are catabolized into

Answer 56

glycerol and fatty acids (transported into the mitochondria)

Question 57

Glycerol as a fuel source

Answer 57

Glycerol is not an important muscle fuel source
- we don’t rely on it for energy

Question 58

Beta oxidation

Answer 58

Converting fatty acids into acetyl-CoA
- “chops” fatty acids into 2 carbon molecules, forming acetyl-CoA (divide by 2)

Acetyl-CoA enter Krebs cycle and leads to aerobic ATP formation by the electron transport chain.

Question 59

Electron Transport Chain

Answer 59

Pumping H+ ions out of the matrix across the inner mitochondrial membrane in order to generate potential energy

• Electrons are carried to the ETC by reduced coenzymes (NADH + H+ and FADH2)
• NADH+H+ and FADH2 release their electrons to protein complexes in the inner mitochondrial membrane called cytochromes, which act as electron acceptors
• H+ ions are separated from their electrons because the cytochromes pass the electrons down the line via a chain of oxidation-reduction reactions
• the energy released in these ox-red reactions allows cytochromes to pump the H+ ions across the inner membrane, creating a concentration and electrical gradient
  (energy pumps hydrogen out of the matrix… the hydrogens can’t come back in without transport channels

The accumulation of H+ is a source of potential energy

Question 60

Chemiosmotic Coupling

Answer 60

capturing the potential energy from the ETC to drive the phosphorylation of ADP —-> ATP

Question 61

Oxygen is the

Answer 61

final electron acceptor

-strong oxidizing agent

If oxygen is not available then oxidative phosphorylation is not possible and we must rely on anaerobic pathways for ATP formation

Question 62

How many ATP are produced in the ETC?

Answer 62

First Pump: 4 H+

Second pump: 4 H+

Third Pump: 2 H+

4 H+ are required to produce and transport 1 ATP

NADH (10 H+) = 2.5 ATP
FADH2 (6 H+) = 1.5 ATP

Question 63

How much ATP is produced from Aerobic Metabolism?

Answer 63

32 ATP

Question 64

Energy from beta oxidation

Answer 64

-2 carbons from the fatty acid can be converted into 1 Acetyl-CoA

• each acetyl-CoA that enters the Krebs cycle produces 10 ATP
• the production of each acetyl-CoA from the fatty acid ( except for the last) also produces 4 ATP

Question 65

How efficient is oxidative phosphorylation at converting foodstuffs into usable energy?

Answer 65

Overall efficiency of aerobic respiration is 34%

66% of energy released as heat

Question 66

Rate-limiting enzyme

Answer 66

Typically, one rate-limiting enzyme found early in a pathway that regulates the rate of a metabolic pathway

• prevents accumulation of products

Question 67

Rate Limiting Enzyme, Stimulators, Inhibitors:

ATP-PC system

Answer 67

Rate Limiting Enzyme: Creatine kinase

Stimulators: ADP

Inhibitors: ATP

Question 68

Rate Limiting Enzyme, Stimulators, Inhibitors:

Glycolysis

Answer 68

Rate Limiting Enzyme: Phosphofructokinase

Stimulators: ADP, AMP, Phosphate ion, High pH

Inhibitors: ATP, CP, citrate, Low pH

Question 69

Rate Limiting Enzyme, Stimulators, Inhibitors:

Krebs cycle

Answer 69

Rate Limiting Enzyme: Isocitrate dehydrogenase

Stimulators: ADP, Ca ++, NAD

Inhibitors: ATP, NADH

Question 70

Rate Limiting Enzyme, Stimulators, Inhibitors:

Electron Transport Chain

Answer 70

Rate Limiting Enzyme: Cytochrome oxidase

Stimulators: ADP, Phosphate ion

Inhibitors: ATP

Question 71

Having a lot of ATP will ______ all the metabolic pathways

Answer 71

slow down

Question 72

Short term, high intensity activities require

Answer 72

high contribution of anaerobic energy production

Question 73

Long term, low to moderate intensity activities require

Answer 73

majority of ATP produced from aerobic sources